A back-wafer contacted silicon-on-glass integrated bipolar process - Part I: The conflict electrical versus thermal isolation

Nanver, Lis K.; Nenadovic, Nebojsa; D'Alessandro, Vincenzo; Schellevis, Hugo; Van Zeijl, Henk W.; Dekker, Ronald; De Mooij, Dick B.; Zieren, Victor; Slotboom, Jan W.

doi:10.1109/TED.2003.820653

A novel silicon-on-glass integrated bipolar technology is presented. The transfer to glass is performed by gluing and subsequent removal of the bulk silicon to a buried oxide layer. Low-ohmic collector contacts are processed on the back-wafer by implantation and dopant activation by excimer laser annealing. The improved electrical isolation with reduced collector–base capacitance, collector resistance and substrate capacitance, also provide an extremely good thermal isolation. The devices are electrothermally characterized in relationship to different heat-spreader designs by electrical measurement and nematic liquid crystal imaging. Accurate values of the temperature at thermal breakdown and thermal resistance are extracted from current-controlled Gummel plot measurements.

A back-wafer contacted silicon-on-glass integrated bipolar process - Part I: The conflict electrical versus thermal isolation / Lis K., Nanver; Nebojsa, Nenadovic; D'Alessandro, Vincenzo; Hugo, Schellevis; Henk W., Van Zeijl; Ronald, Dekker; Dick B., De Mooij; Victor, Zieren; Jan W., Slotboom. - In: IEEE TRANSACTIONS ON ELECTRON DEVICES. - ISSN 0018-9383. - STAMPA. - 51:1(2004), pp. 42-50. [10.1109/TED.2003.820653]